Bandwidth Modification for Transparent Capacity Management in a Carrier Network

ABSTRACT

Some embodiments provide a capacity management agent that modifies bandwidth that is allocated between an end user and a carrier network by caching requested content that is streamed at a first rate and then providing the cached content to the end user through the carrier network at a second rate. The agent performs a process that includes receiving data intended for a service region of the carrier network from an external data network. The process identifies resource availability at the service region. Next, the process passes the data to the service region at the first rate when the resource availability at the service region is not less than a threshold amount and caches the data for passing to the service region at the second rate that consumes fewer carrier network resource than the first rate when the resource availability at the service region is less than the threshold amount.

TECHNICAL FIELD

The present invention relates to systems and methods for maximizingcarrier network capacity.

BACKGROUND ART

Much of the digital content that end users send and receive passesthrough various data networks that collectively form the Internet. Endusers gain access to these data networks through one or more carriernetworks. Carrier networks include internet service providers (ISPs)that have provided dial-up connectivity and that now provide wiredbroadband connectivity (e.g., Digital Subscriber Line (DSL), cable, andfiber optic) through which end users access the Internet while at homeor at the office. Carrier networks also include wireless carriers suchas AT&T, Verizon, Sprint, and T-Mobile that provide wireless access tothe Internet.

The wireless carriers have invested heavily in deploying wirelessnetworks that are accessible by end users across multiple regions. FIG.1 illustrates components of a wireless carrier network 105. As shown,the wireless carrier network 105 includes a radio access network (RAN)110, a mobile switching center (MSC) 120, a Serving GPRS (General PacketRadio Service) Support Node (SGSN) 130, a Gateway GPRS Support Node(GGSN) 140, a Home Location Register (HLR) 150, and a set of databases160.

The wireless carrier network 105 may include multiple RANs. In thisfigure, the RAN 110 is depicted as a UMTS (Universal MobileTelecommunications System) Terrestrial Radio Access Network (UTRAN) thatincludes a Node B 170 and a Radio Network Controller (RNC) 180. The NodeB 170 provides an air interface that spans several hundred meters. TheNode B 170 generates a service region that allows one or more end usersubscriber devices 190 that are located in the service region towirelessly connect to circuit switched (i.e., voice) and packet switched(i.e., data) services of the wireless carrier network. A typicalwireless carrier network includes multiple Node Bs for each RAN andmultiple RANs to provide overlapping service regions that providecontinuous wireless service.

The circuit switched services are provided by the MSC 120. The MSC 120provides call switching and mobility management functionality to allowend user devices to place calls to the Public Switched Telephone Network(PSTN) 190.

The packet switched services are provided by the SGSN 130 and the GGSN140. The SGSN 130 performs packet routing, mobility management, andauthentication functionality within a particular geographic serviceregion when the end user device requests data services through thewireless carrier network 105. The GGSN 140 provides interworking betweenthe GPRS based data packets of the wireless carrier network 105 andInternet Protocol (IP) based data packets of external data networks suchas the Internet.

The HLR 150 is one or more databases that store end user information.The HLR 150 identifies what services a particular end user has accessto, location of the particular end user, and other end user subscriberaccount information. The set of databases 160 compliments the HLR 150and provides additional information about end user parameters andnetwork parameters. For example, the set of databases 160 storesinformation about the end users' devices (e.g., make and model) and thecongestion at each Node B or RAN of the wireless carrier network.

Carrier networks, especially wireless carrier networks, are continuallydealing with capacity issues in order to meet increased demand for theirservices. The increased demand comes in the form of new end users thatpreviously did not have data access and new and more powerful end userdevices that utilize the carrier networks' services to consume morefeature-rich content such as videos, music, and other interactivecontent. These devices include smartphones (e.g., Apple's iPhone andother smartphones powered by the Android or Windows Phone 7 operatingsystems), tablet devices, and laptops or other computing devices withwireless connect cards that allow the devices to wirelessly accessservices of the carrier network.

Carrier networks are sometimes unable to keep up with the increase indemand. This is especially true for wireless carrier networks that haveaccess to a limited wireless spectrum and are therefore much morelimited in bandwidth than wired carrier networks. Consequently, endusers may experience degraded or unavailable service. For example, someend users may be unable to connect to a wireless carrier network duringpeak usage hours. These end users will be unable to access wireless dataservices. This situation is further exacerbated by end users withunlimited access plans that can disproportionally consume the carriernetwork's bandwidth.

Some carrier networks have introduced monthly caps on data usage in anattempt to limit end user content consumption. However, these caps donot improve the capacity of the carrier network during times of peakusage when the number of end users accessing the carrier network'sservices exceeds the available capacity or in major metropolitan areaswhere the number of end users in a particular service region exceeds theavailable capacity at that particular service region. Upgrading existinginfrastructure imposes significant costs on the carrier network. Forexample, upgrading from a 3G to a 4G (Worldwide Interoperability forMicrowave Access (WiMAX) or Long Term Evolution (LTE)) data networktakes several years and hundreds of millions in cost to rollout.

Accordingly, there is a need to better utilize the existing resources ofa carrier network to maximize the available capacity of a carriernetwork. There is a need to do so without modifying existing equipmentand existing configurations of the carrier networks so thatimplementation, maintenance, and integration costs are minimized.

SUMMARY OF THE INVENTION

Some embodiments provide a capacity management agent that seamlesslyintegrates with existing components of a carrier network and thatimproves the capacity of the carrier network. The capacity managementagent also enables the carrier network to better monetize underutilizedresources, provide quality of service controls, and provide parentalcontrols.

In some embodiments, the capacity management agent improves carriernetwork capacity by modifying user content requests that are submittedthrough the carrier network. The modifications are made to adjust theamount of bandwidth that is consumed when streaming the requestedcontent from the content provider to the requesting end user. Themodifications to the end user content requests are based on carriernetwork condition parameters, end user parameters, or both. In someembodiments, the modifications include modifying a Uniform ResourceLocator (URL) that is associated with the end user request or a querystring of the URL that is associated with the end user request. In someembodiments, the modifications include modifying header information ofthe packet that is associated with the end user request.

The modifications specify various quality settings and bitrate encodingsfor the content that is being requested. The modifications can alsospecify settings that optimize content playback on a particular end userdevice. In some embodiments, the modifications populate various datafield in the content request with values in order to reduce messageexchanges between end users and content providers.

In some embodiments, the capacity management improves carrier networkcapacity by modifying the bandwidth that is allocated between each enduser and the carrier network. Specifically, the capacity managementagent caches requested content that is streamed from a content providerat a first rate and the capacity management agent provides the contentto the requesting end user through the carrier network at a second rate.In some embodiments, when the available resources at the service regionin which the requesting end user is located are less than a specifiedthreshold, the second rate at which content is provided to the end useris less than the first rate thereby conserving resources of the carriernetwork. In some embodiments, when the available resources at theservice region in which the requesting end user is located are greaterthan a specified threshold, the second rate at which content is providedto the end user is greater than the first rate to ensure that theresources do not remain underutilized and so that the carrier networkcan bill for the usage of the resources. Accordingly, bandwidthmodification may be used to ensure proportional bandwidth consumptionbetween end users that are utilizing the carrier network's services,better monetize the carrier network's underutilized resources, andprovide quality of service controls.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to achieve a better understanding of the nature of the presentinvention, a preferred embodiment of the capacity management agent willnow be described, by way of example only, with reference to theaccompanying drawings in which:

FIG. 1 illustrates components of a wireless carrier network.

FIG. 2 illustrates a carrier network operating with a capacitymanagement agent of some embodiments.

FIGS. 3 and 4 present processes performed by the capacity managementagent to dynamically modify end user content requests based on carriernetwork condition parameters in accordance with some embodiments.

FIG. 5 presents a message exchange for modifying a content request toconserve carrier network resources in accordance with some embodiments.

FIG. 6 illustrates using the capacity management agent to improvecapacity of the carrier network by modifying content requests to includeautomatically populated data in accordance with some embodiments.

FIG. 7 illustrates modifying end user submitted content requests toautomatically redirect the end user to an appropriate site in accordancewith some embodiments.

FIG. 8 presents a process performed by the capacity management agent tomodify a content request based on end user parameters.

FIG. 9 illustrates using the capacity management agent to bettermonetize the carrier network resources.

FIG. 10 presents a process performed by the capacity management agent todynamically adjust the bandwidth usage of end users in order to improvecapacity of the carrier network in accordance with some embodiments.

FIG. 11 presents a message exchange to illustrate the bandwidthmodification that is performed by the capacity management agent inaccordance with some embodiments.

FIG. 12 presents a process performed by the capacity management agent tomodify bandwidth for purposes of monetizing the available resources ofthe carrier network in accordance with some embodiments.

FIG. 13 presents a process performed by the capacity management agent tomodify bandwidth for purposes of providing QoS controls in accordancewith some embodiments.

FIG. 14 presents a process for performing content request modificationand bandwidth modification in accordance with some embodiments.

FIG. 15 illustrates a computer system or server with which someembodiments are implemented.

DETAILED DESCRIPTION

In the following detailed description, numerous details, examples, andembodiments of a capacity management agent that transparently improvescapacity for a carrier network is set forth and described. It will beclear and apparent to one skilled in the art that the capacitymanagement agent is not limited to the embodiments set forth and thatthe capacity management agent may be practiced without some of thespecific details and examples discussed.

I. Overview

Some embodiments provide a capacity management agent for a carriernetwork. The capacity management agent operates to transparently improvethe capacity of the carrier network. This allows for greatersimultaneous usage of the carrier network without having to upgrade theexisting infrastructure or resources of the carrier network. Thecapacity management agent seamlessly integrates with the existingcomponents of the carrier network. In some embodiments, the carriernetwork is a wireless carrier network that provides end users withwireless access to data networks such as the Internet. However, itshould be apparent to one of ordinary skill in the art that the systemsand methods provided below are applicable to any carrier network.

In some embodiments, the capacity management agent improves the capacityof the carrier network by modifying end user content requests that aresubmitted through the carrier network. The modifications adjust theamount of bandwidth that is consumed when the requested content isstreamed from the content provider through the carrier network to therequesting end user. The content provider is the entity that hosts therequested content on its servers. The capacity management agent does notalter the content once streaming has commenced from the contentprovider. Furthermore, the modifications are transparently performed ina manner that does not affect the operation of the carrier network, endusers, or content providers.

The modifications to the end user content requests are based on carriernetwork condition parameters, end user parameters, or both. In someembodiments, carrier network condition parameters specify load, ameasure of resource usage, number of active users, and other conditionsat a particular Point of Presence (POP) of the carrier network. In someembodiments, the measure of resource usage includes a measure ofbandwidth usage, a measure of load, a measure of active users, or someother measure of congestion. For a wireless carrier network, a POPincludes a service region that is generated by a cellular tower such asNode B. In some embodiments, end user parameters specify the device thatis used by the end user, the supported display resolution of the enduser device, and the end user subscriber information as some examples.

In some embodiments, the capacity management agent modifies a UniformResource Locator (URL) that is associated with an end user request or aquery string of the URL that is associated with the end user request. Insome embodiments, the modifications include modifying header informationof at least one packet that is associated with an end user request.

The modifications set various configurable parameters for the contentthat is being requested. For example, these configurable parametersinclude content quality settings (e.g., resolution, encoding rate,etc.), settings that optimize content playback for a particular enduser, and values used in populating data fields that are associated withthe content that is being requested.

In some embodiments, the capacity management agent improves the capacityof the carrier network by dynamically and transparently adjusting thebandwidth that is allocated between an end user and the carrier networkbased on changing network conditions. To do so, the capacity managementagent intercepts requested content that is streamed from a contentprovider and that is intended for the carrier network. The requestedcontent is passed at a first rate from the content provider. Thecapacity management agent caches the content and provides the cachedcontent to the appropriate requesting end user through the carriernetwork at a bandwidth limited second rate.

In some embodiments, the capacity management agent provides quality ofservice (QoS), redirection, and parental controls to improve thecapacity of the carrier network. In some embodiments, the QoS controlsallow the carrier network to ensure that unlimited access end users donot disproportionately consume carrier network resources. Unlimitedaccess end users include those end users that pay a flat fee to accessunlimited amounts of data. This is in contrast to pay-per-access usersthat pay a certain amount for each unit of accessed data (e.g., eachmegabyte). Moreover, the QoS controls allow for better monetization ofthe available bandwidth by providing pay-per-access end users a higherlevel of service as compared to unlimited usage end users. Whenperforming redirection, the capacity management agent improves thecapacity of the carrier network by reducing the number of messageexchanges that are needed to satisfy a particular end user contentrequest. In so doing, the capacity management agent frees bandwidth thatwould otherwise be consumed in performing the extraneous messageexchanges. When performing parental controls, the capacity managementagent restricts illicit, lewd, or other unapproved content from passingthrough the carrier network to the service regions, thereby freeingbandwidth for other approved uses. Also when performing parentalcontrols, the capacity management agent may monitor end user usage andlimit bandwidth usage for an end user that is a member of a group orfamily plan and that is disproportionately consuming bandwidth for thegroup or where the usage for the group exceeds an allotment threshold.

II. Capacity Management Agent

FIG. 2 illustrates a carrier network 210 operating with a capacitymanagement agent 220 of some embodiments. The capacity management agent220 may be part of the carrier network 210 or external to the carriernetwork 210. The capacity management agent 220 may be operated by thecarrier network 210 or by a third party operator such as a ContentDelivery Network (CDN). In some embodiments, the capacity managementagent 220 transparently operates with the existing carrier network 210by intercepting content requests that pass from the carrier network 210to an external data network 230. In some embodiments, the capacitymanagement agent 220 operates on IP based traffic and is thereforepositioned in proximity to the packet switching components of thecarrier network 210 such as the GGSN. Content requests include HyperTextTransfer Protocol (HTTP) GET messages. In some embodiments, the capacitymanagement agent 220 intercepts downstream traffic that passes from theexternal data network 230 to the carrier network 210.

The capacity management agent 220 includes a rules engine that specifiesvarious processes for modifying content requests and for dynamicallyadjusting bandwidth. The rules engine is executed using computingresources of a server. The server may include a physical computingmachine with a processor, memory, storage, and network connectivity.Alternatively, the server may include a virtual machine that is run onan existing computing machine of the carrier network 210, wherein eachvirtual machine is provided exclusive or shared access to a particularset of computing resources (e.g., processor, memory, storage, etc.) ofthe machine. In some embodiments, the functionality of the capacitymanagement agent is integrated as one or more virtual machines thatexecute on packet switching components (i.e., GGSN) of the carriernetwork. In some embodiments, the capacity management agent 220 alsoincludes one or more databases for storing rules for the rules engine,for storing arguments that are used to modify content requests fordifferent content providers, and for storing a local copy of data thatis stored within the databases of the carrier network 210 (e.g., enduser device information, end user service subscription information,etc.).

Though FIG. 2 shows one capacity management agent 220 for the carriernetwork 210, it should be apparent to one of ordinary skill that thecarrier network 210 can include multiple capacity management agents atdifferent locations of the carrier network at which traffic passes fromthe carrier network 210 to the external data network 230. Moreover,multiple capacity management agents may operate at a single location ina load balanced manner of operation.

A. Content Request Modification

In the carrier network, streaming content often consumes the majority ofthe available bandwidth. Streaming content includes video, audio, andinteractive content such as video games. When an end user requests aparticular content stream from a content provider, a default encoding ofthe stream is returned from the content provider. The default encodingspecifies a particular bitrate for the content. This bitrate consumes acertain amount of bandwidth of the carrier network which reduces theavailable resources and capacity of the carrier network. The greater thebitrate for the streaming content, the larger the impact to theresources and capacity of the carrier network.

In many cases, the content provider stores multiple encodings for thesame content. Each encoding specifies a different bitrate that altersthe amount of bandwidth that would be consumed when streaming thecontent to the end user. Therefore, to conserve the carrier networkbandwidth and thereby increase the carrier network capacity, thecapacity management agent intercepts and modifies the end user submittedrequest to explicitly request a lower quality encoding of the requestedcontent stream than the default encoding. In response to the modifiedcontent request, the content provider streams the requested contentusing an encoding that consumes less bandwidth than the default encodingthat would otherwise be provided by the content provider.

Less bandwidth and therefore less capacity of the carrier network isconsumed in delivering the content in response to the modified contentrequest. Moreover, bandwidth usage is reduced without the capacitymanagement agent or the carrier network transcoding or processing thestream as it is passed from the content provider through the carriernetwork to the end user.

In some embodiments, providing the lower quality encoding improves theuser experience. For example, the wireless carrier may provide a certainlimited amount of bandwidth per end user that is insufficient to supportstreaming of high quality content. As a result, buffering occurs at theend user device which creates an interrupted user experience. However,by modifying the content request to specify lower quality content, theuser is less likely to experience buffering thereby improving the userexperience. As another example, many wireless devices that are used toaccess streaming content from a wireless carrier network have lowresolution displays. These low resolution displays are often unable todisplay the resolution specified within the default encoding of therequested content stream. Accordingly, no quality is lost when modifyingthe end user content request to request a lower quality encoding of thecontent. The lower quality encoding utilizes less processing resourcesof the end user device, allowing for smoother playback and lower powerconsumption. The end user device avoids having to perform processorintensive operations to downscale and process the greater amount of datathat is encoded in a higher quality encoding. Accordingly, by streamingless data to the end user device, the end user device can begindisplaying the content sooner, with less buffering, and with lessinterruption.

In some embodiments, the capacity management agent modifies end usercontent requests based on carrier network condition parameters. As notedabove, these condition performance parameters specify load, resourceusage, number of active users, and other conditions at a particular POPof the carrier network. For a wireless carrier network, a POP includes aservice region that is generated by a cellular tower such as Node B. Thecapacity management agent retrieves the condition parameters from thedatabases of the carrier network. For example, the HLR database 150 andthe set of databases 160 of FIG. 1. The capacity management agent isconfigured with access to these databases and the agent periodicallypulls the condition parameters from the databases. In some embodiments,the condition parameters serve as inputs to the rules engine of thecapacity management agent. The rules engine executes various processesto determine whether to and how to modify content requests. In someembodiments, content requests from a particular POP of a carrier networkare modified when that particular POP experiences high load and capacityat that POP becomes limited as a result. For example, the capacitymanagement agent modifies content requests that come from a particularPOP when 90% of the resources at that particular POP are utilized.

FIG. 3 presents a process 300 performed by the capacity management agentto modify end user content requests based on carrier network conditionparameters in accordance with some embodiments. The process 300 beginswhen an end user submits a content request through the carrier networkand the capacity management agent intercepts the request as it is passedfrom the carrier network to an external data network.

The process analyzes the content request to identify (at 310) a contentprovider from which content is being requested. The content provider isidentified by analyzing the URL that is provided in the content request.In some embodiments, the content provider is identified from the domain,hostname, or entire URL that is provided in the content request. Forexample, a content request for a YouTube video specifies the“www.youtube.com” domain. The process determines (at 320) whether theidentified content provider is a content provider that supports requestmodification. A list of supported content providers is configured in therules engine of the capacity management agent by the capacity managementagent administrator or carrier network administrator. The configuredlist is stored as a set of records to a computer readable storage mediumof the capacity management agent. The process performs a lookup of theidentified content provider against the configured list to make thedetermination.

When the identified content provider does not support modified contentrequests, the process passes (at 370) the content request through to theexternal data network without modification. From the external datanetwork, the content request is routed to the identified contentprovider.

When a content provider that supports content request modification isidentified (at 320), the process monitors (at 330) the carrier networkconditions to determine whether content request modification isnecessary. As noted above, the carrier network conditions are retrievedfrom one or more databases of the carrier network. The conditionsidentify whether the particular carrier network POP at which the contentrequest originates is congested (i.e., running low on availablecapacity) and whether the content request should be modified in order toreduce resource consumption. In some embodiments, the conditions alsoidentify whether neighboring POPs are congested in order to account forend user mobility and handover between POPs. The process determines (at340) whether the retrieved conditions exceed a usage threshold. As asimplified example, the usage threshold may specify 10% availablebandwidth at the particular POP and when the available bandwidth fallsbelow 10%, the process modifies content requests in order to conservebandwidth at the particular POP and thereby improve the capacity of thecarrier network.

When the retrieved conditions do not exceed the usage threshold, theprocess passes (at 370) the content request through to the external datanetwork without modification. Otherwise, the process identifies (at 350)what arguments can be used to modify the content request. As will bediscussed in greater detail below, these arguments can be added to thequery string of the content request URL or can be inserted into theheader of the content request packet to modify the content request.Different content providers utilize different arguments. Therefore, therules engine is configured with different arguments for differentcontent providers. The arguments are stored to the computer readablestorage medium of the capacity management agent. The process modifies(at 360) the content request with the arguments that are identified at350 based on the determined carrier network conditions. In this case,the process passes (at 370) the modified content request through theexternal data network to the content provider and the process ends. Insome embodiments, the modified content request causes the contentprovider to return the requested content at a lower quality setting(e.g., reduced bitrate or lower resolution) that consumes fewerresources of the carrier network.

It should be apparent to one of ordinary skill in the art that the orderin which process 300 is performed may be modified without affecting theoperation of the process 300. For example, FIG. 4 presents a similarprocess to that of FIG. 3 in which steps 310 and 320 are performed aftersteps 330 and 340. Accordingly, in FIG. 4, the process monitors (at 410)the carrier network condition parameters to determine (at 420) whetherthe conditions exceed a threshold before identifying whether the contentprovider is one that supports request modification at steps 430 and 440.

FIG. 5 presents a message exchange for modifying a content request toconserve carrier network resources in accordance with some embodiments.The figure includes an end user 510, carrier network 520, capacitymanagement agent 525, and content provider 530. The message exchangebegins when the end user 510 communicatively couples to a service regionof the carrier network 520 and the end user 510 submits (at 540) arequest for content of the content provider 530 in an external datanetwork. As shown, the end user 510 requests a video stream entitled“videoABC” from the www.provider1.com content provider 530. The requestis received (at 540) at the carrier network 520. In this figure, it isassumed that the service region in which the end user 510 is located iscongested.

The carrier network 520 forwards the request to the content provider 530through an external data network. However, before being routed throughthe external data network, the capacity management agent 525 intercepts(at 550) and analyzes the request to determine whether the requestshould be modified as per the process 300 of FIG. 3 or some similarprocess. The capacity management agent 525 receives (at 550) networkcondition parameters that report on the condition of the carriernetwork. Specifically, the network condition parameters identify thatthe service region from which the request originates is congested andthat resources at that service region are below an available usagethreshold. Therefore, the capacity management agent 525 modifies thecontent request before sending it to the content provider 530 throughthe external data network.

In this figure, the content request is modified by appending a qualitysetting argument to the query string of the URL. Specifically, the querystring is modified to include “?Quality=1”. This argument specifies alow quality setting for the video stream that is returned by the contentprovider 530 and overrides a higher quality default setting (e.g.,Quality=5) for the video stream that would otherwise have been returnedby the content provider when such an argument is omitted from the querystring.

When the content provider 530 receives the modified request, the contentprovider 530 returns (at 560) the low quality stream for the requested“videoABC” video instead of the default higher quality stream. Thestream passes from the content provider 530 to the capacity managementagent 525, from the capacity management agent 525 to the carrier network520, and from the carrier network 520 to the end user 510 without anyfurther modifications or processing by the capacity management agent525. The modification is transparently performed by the capacitymanagement agent 525 as the end user 510 and the carrier network 520 areunaware of the modification to the content request. Additionally, themodification occurs without changes to the operation or configuration ofthe carrier network 520. The resources are conserved even when the enduser 510 is handed over from the congested service region to anotherservice region.

It should be apparent to one of ordinary skill in the art that differentcontent providers utilize different query string arguments to specifyquality settings. Accordingly, the capacity management agent modifiesthe query differently for different content providers. For example, tospecify a quality setting for a www.youtube.com video, the capacitymanagement agent appends the “&fmt=X” query string argument to thecontent request URL where the “X” represents a quality setting value forthe requested video.

In some embodiments, the capacity management agent modifies the headerof the content request packet in order to specify various arguments forthe content that is to be returned by the content provider. The packetheader modification may be performed in addition to or instead of thequery string modification presented above.

In some embodiments, the packet header modification may be performedusing “X-headers”. X-headers are non-standard headers that can beinserted into an HTTP header or other headers of the content requestpacket. Different content providers may support different X-headers.Accordingly, the rules engine of the capacity management agent isconfigured with the supported X-headers for a particular contentprovider. These supported header arguments are stored to the computerreadable storage medium of the capacity management agent.

The example below illustrates an HTTP header with various standardheader fields:

Host: www.examplehost.comUser-Agent: Mozilla/5.0 (Linux x86_(—)64; en-US; rv:1.9.2.11)Firefox/3.6.11Accept: text/html,application/xhtml+xml,application/xml;q=0.9,*/*;q=0.8Accept-Language: en-us,en;q=0.5Accept-Encoding: gzip,deflateAccept-Charset: ISO-8859-1,utf-8;q=0.7,*;q=0.7

Keep-Alive: 115

Connection: keep-aliveCookie: simple=165145323.2009124443Cache-Control: max-age=0

The capacity management agent can modify such a header to include aquality setting field that is used by a particular content provider toselect the bitrate or encoding for the content being requested. Theexample below illustrates an HTTP header that is modified with aX-header field for specifying a quality setting for a video stream thatis to be returned by the particular content provider:

Host: www.examplehost.comUser-Agent: Mozilla/5.0 (Linux x86_(—)64; en-US; rv:1.9.2.11)Firefox/3.6.11Accept: text/html,application/xhtml+xml,application/xml;q=0.9,*/*;q=0.8Accept-Language: en-us,en;q=0.5Accept-Encoding: gzip,deflateAccept-Charset: ISO-8859-1,utf-8;q=0.7,*;q=0.7

Keep-Alive: 115

Connection: keep-aliveCookie: simple=165145323.2009124443Cache-Control: max-age=0

X-Quality: 1

In the above modified header, the capacity management agent introducedthe “X-Quality: 1” field to specify the quality setting for the contentbeing requested.

In some embodiments, modifying the content request (i.e., modifyingquery strings or packet headers) improves the capacity of the carriernetwork by automatically populating the content request with data thatreduces the number of messages that are exchanged between an end userand a content provider. For example, an end user may access a websitethat locates restaurants within a specified region. The end user firstsubmits a request for and receives the homepage in which the end usercan enter his location information. The end user then submits a secondrequest that includes his location information to the content providerand the content provider responds with a second page that displays therestaurants that are closest to the end user. The capacity managementagent can leverage the information within the carrier network databasesto perform the above example in a single message exchange. In so doing,the carrier network avoids passing the homepage the second contentrequest thereby saving bandwidth and improving capacity.

FIG. 6 illustrates using the capacity management agent to improvecapacity of the carrier network by modifying content requests to includeautomatically populated data in accordance with some embodiments. FIG. 6includes an end user 610, carrier network 620, capacity management agent625, and content provider 630. In this figure, it is assumed that theservice region in which the end user is located 610 is congested.

The end user 610 submits (at 640) a content request to the contentprovider 630 that identifies restaurants in an area. The content requestis forwarded from the end user 610 to the carrier network 620. Thecapacity management agent 625 receives (at 650) the content request fromthe carrier network 620. The capacity management agent 625 also receivesnetwork condition parameters that include the location of the requestingend user 610. In some embodiments, the location is determined byidentifying the service region from which the request originates.

The capacity management agent 625 identifies the content provider 630from the content request. The capacity management agent 625 isconfigured with a set of rules that specify arguments that are insertedto the query string or header of the content request for the identifiedcontent provider 630. In this figure, the capacity management agent 625inserts location information for the end user 610 into the query stringin a format that is supported by the content provider 630. However, itshould be apparent that the location information may also be inserted asa query string argument into a URL in some embodiments. The modifiedcontent request is then passed (at 655) to the content provider 630.Rather than return the homepage as was specified by the end user 610 inthe original content request, the content provider 630 provides (at 660)content that identifies restaurants within the surrounding area of theend user 610. This improves the end user experience as the end userobtains desired information in fewer transactions. This also improvesthe capacity of the carrier network by reducing the traffic that is sentto and received from the end user. Similar operation can be leveragedfor other such sites. For example, when an end user requests a mappingsite for directions, the starting location of the end user can beobtained from the HLR database of the carrier network and automaticallypopulated in the content request before it is passed to the mappingcontent provider.

In some embodiments, the capacity management agent improves the capacityof the carrier network by modifying content requests to automaticallyredirect end users to an appropriate site. In so doing, the capacitymanagement agent reduces the number of message exchanges that wouldotherwise occur in order to redirect the end users. This often occurswhen end users that use portable wireless devices request a particularwebsite from a content provider and the content provider redirects theend users to a mobile version for that website. For example, whenrequesting the www.yahoo.com website, an end user that submits such arequest from a smartphone is provided a redirection link to them.yahoo.com website. The end user then submits a second request for them.yahoo.com before being provided the content from the appropriate site.By modifying the content request at the capacity management agent, thesecond message exchange is eliminated. FIG. 7 illustrates modifying enduser submitted content requests to automatically redirect the end userto an appropriate site in accordance with some embodiments.

In some embodiments, the capacity management agent improves the capacityof the carrier network based on end user parameters. End user parametersinclude the device used by the end user to submit a request, thesupported display resolution of the end user device, and the end usersubscriber information (e.g., demographic information, subscribedservices, etc.) as some examples. Such information is available and canbe pulled from the databases of the carrier network. In someembodiments, the capacity management agent uses this information tooptimize the modifications that are made to the end user requests.Specifically, by identifying the end user device or its displayresolution, the capacity management agent can modify the end usersubmitted content request to select a video stream that is optimal fordisplay on the user device.

As noted above, providers of streaming content often return a requestedcontent stream with a default quality setting irrespective of whatdevice the stream is to be displayed on. For a wireless carrier network,many end users request content using smartphones. Some smartphones havea maximum display resolution of 320×240 pixels. Accordingly, bandwidthis wasted when streaming content at a display resolution of 640×480 tosuch an end user. Moreover, the end user experience is detrimentallyaffected since the end user device processes the stream to downscale itto the 320×240 resolution. Such downscaling is processor intensive andmay result in interrupted playback of the stream. Additionally,processor intensive tasks such as downscaling drain the battery of thedevice. Lastly, playback can be interrupted as repeated buffering canoccur if sufficient bandwidth is not available to stream the higherquality stream.

However, by modifying the content request with end user parameters, thereturned content can be optimized to improve carrier network capacitywhile also improving the user experience. FIG. 8 presents a process 800performed by the capacity management agent to modify a content requestbased on end user parameters in accordance with some embodiments. Thisprocess 800 can be performed in conjunction with or independent ofprocess 300 described above.

The process begins when the capacity management agent receives (at 810)an end user submitted request. The process identifies (at 820)parameters for the end user that submits the content request. Theseparameters are identified by querying the databases of the carriernetwork with one or more identifiers for the requesting end user (e.g.,Subscriber Identity Module (SIM), IP address, session identifier). Forexample, the end user device information can be obtained from asubscriber database of the carrier network such as the HLR. In someembodiments, a copy of the information from the carrier networkdatabases is stored locally at the capacity management agent. In somesuch embodiments, the end user parameters can be obtained moreefficiently without the need to submit queries to the databases of thecarrier network.

Next, the process modifies (at 830) the received content request basedon the end user parameters. As presented above, the modifications mayinclude inserting query string arguments into the URL that is associatedwith the content request. The modification may also include insertingheader fields into the header of the content request packet. In theexample below, end user demographic information and device informationare inserted into an HTTP header of the end user content request:

Host: www.examplehost.comUser-Agent: Mozilla/5.0 (Linux x86_(—)64; en-US; rv:1.9.2.11)Firefox/3.6.11Accept: text/html,application/xhtml+xml,application/xml;q=0.9,*/*;q=0.8Accept-Language: en-us,en;q=0.5Accept-Encoding: gzip,deflateAccept-Charset: ISO-8859-1,utf-8;q=0.7,*;q=0.7

Keep-Alive: 115

Connection: keep-aliveCookie: simple=165145323.2009124443Cache-Control: max-age=0X-Demographic: gender=Male;age_range=18-39;zip=90405

X-Handset: Droid X X-Resolution: 854×480

It should be apparent to one of ordinary skill in the art that thecapacity management agent may be configured with rules that cause thecapacity management agent to perform the above modification forspecified domains or content providers. Different modifications may bemade for different domains or content providers. Additionally, themodifications may be performed when a usage threshold at a POP fromwhich the request originates is met or exceeded. In some embodiments,the modifications based on carrier network condition parameters takeprecedence over the modifications that are based on the end userparameters. In some embodiments, the modifications based on the end userparameters are used to optimize the modifications that are made based onthe carrier network condition parameters.

In addition to or instead of improving carrier network capacity, thecontent request modifications that are performed by the capacitymanagement agent may be used to better monetize the carrier networkresources, provide QoS, and provide parental controls. FIG. 9illustrates using the capacity management agent to better monetize thecarrier network resources.

FIG. 9 includes an end user 910, carrier network 920, capacitymanagement agent 925, and content provider 930. In this figure, it isassumed that the end user 910 is located in an uncongested serviceregion where the resources of the service region are underutilized. Itis also assumed that the end user 910 is a pay-per-access user that paysfor each megabyte of data that is downloaded from the carrier network.For these pay-per-access end users, the carrier network prefersincreasing the amount of data that is streamed to the end user 910 whenthe resources of the service region in which the end user is located areunderutilized. This is so that the available resources do not remainidle and so that the carrier network can bill for the end user's 910usage of these resources. Accordingly, the capacity management agent isconfigured to modify the content request so that a stream that is higherin quality than a default stream is returned to the user from a contentprovider.

As shown, the end user 910 requests (at 940) the videoABC stream fromthe www.provider1.com content provider. The request is received at thecarrier network 920. The carrier network 920 passes the request to anexternal data network. The capacity management agent 925 intercepts (at950) the request before it is passed to the external data network. Thecapacity management agent 925 also retrieves carrier network conditionparameters for the service region and end user parameters. The carriernetwork condition parameters identify that the available resources atthe servicer region in which the request originates are above a certainthreshold indicating that the resources of that service region areunderutilized. For example, the resources at the service region are lessthan 60% utilized. The end user parameters identify the end user 910 asa pay-per-access end user.

Based on the carrier network condition parameters, the capacitymanagement agent 925 identifies that the resources at the service regioncan be better monetized by modifying the content request to pass ahigher quality stream to the end user 910. Accordingly, the capacitymanagement agent 925 modifies the content request query string byappending the quality setting argument to the query string and settingthe value for the argument to specify a high quality stream. In thisfigure, the modified content request includes the query string argument“?Quality=9”. The capacity management agent 925 passes the modifiedcontent request to the content provider 930 through the external datanetwork. The content provider then returns (at 960) the videoABC streamat a bitrate that consumes 750 kbps in contrast to the low qualitybitrate of the videoABC stream that was returned in FIG. 5 and thatconsumed 160 kbps.

Similar operation of the capacity management agent can be used toprovide QoS functionality. Specifically, the capacity management agentcan be configured to modify content requests from unlimited usage endusers to request lower quality streams and to modify content requestsfrom pay-per-access end users to request higher quality streams. In sodoing, a first QoS is provided to the unlimited usage end users and asecond QoS is provided to the pay-per-access end users.

In some embodiments, the capacity management agent is configured toprovide parental controls and limit end users access to illicit, lewd,or other unapproved content. Such restrictions can be imposed duringperiods of peak usage where carrier network resources are scarce. Insuch scenarios, the capacity management agent can be configured toprevent content requests for the unapproved content from being forwardedfrom the carrier network to the specified content provider. The capacitymanagement agent may instead return an error message to the end user.This ensures that resources are not utilized for unapproved uses.

In some other embodiments, the parental controls provided by thecapacity management agent can be used to monitor end user usage so thata particular end user does not exceed an allotted amount of resources.Specifically, for an end user that is a member of a group or familyplan, the capacity management agent may limit the bandwidth when thatend user disproportionately consumes bandwidth for the group or wherethe usage for the group has exceeded an allotment threshold.

To provide such parental controls, the capacity management agent of someembodiments is configured with one or more rules that restrict access toa set of predefined sites or domains when network performance parametersreach a particular threshold. Additionally, the capacity managementagent can be configured to prevent access to particular sites thatconsume large amounts of bandwidth when resource usage exceeds aparticular threshold. For example, the YouTube video streaming site maybe restricted to ensure that bandwidth is available for other sites.

B. Transparent Bandwidth Modification

In some embodiments, the capacity management agent provides alternatemeans with which to improve the capacity of the carrier network, bettermonetize available resources, or provide QoS controls. In some suchembodiments, the capacity management agent dynamically adjusts thebandwidth that is allocated for downstream data traffic passing from thecarrier network to end users.

In some embodiments, the capacity management agent monitors the carriernetwork condition parameters to identify congested service regions ofcarrier network. To improve capacity for these congested areas, thecapacity management agent intercepts data that passes from an externaldata network and that is intended to reach an end user that is locatedwithin one of the congested service regions. The capacity managementagent caches the intercepted data. Then, the capacity management agentpasses the data from its cache through the carrier network to the enduser at a bandwidth limited reduced rate. Specifically, the capacitymanagement agent modifies the bandwidth based on the determined amountof congestion at the destination service region. The greater the amountof congestion, the more the capacity management agent restrictsbandwidth. In this manner, the capacity management agent can chokebandwidth usage of certain users and preserve bandwidth for other users.Such bandwidth management ensures that capacity is available for moreusers at times of peak usage and that certain end users do notdisproportionately consume the carrier network bandwidth whendownloading large files or when streaming audio or video content.

FIG. 10 presents a process 1000 performed by the capacity managementagent to dynamically adjust the bandwidth usage of end users in order toimprove capacity of the carrier network in accordance with someembodiments. The process 1000 begins when data is being streamed from anexternal data network to an end user of the carrier network.

The process monitors (at 1010) the carrier network condition parametersto identify resource usage throughout the carrier network.Alternatively, the process may monitor the condition parameters for aset of service regions of the carrier network that the capacitymanagement agent manages. The carrier network condition parameters areretrieved by polling the databases of the carrier network. As earliernoted, these databases identify real-time traffic conditions, areas ofcongestion, number of active users, etc. across the various serviceregions of the carrier network. Based on the monitored conditionparameters, the process identifies (at 1015) congested service regionswhere resources are limited.

While monitoring the carrier network condition parameters, the processreceives (at 1020) downstream data traffic that is intended for endusers of the carrier network. The process selects which content (at1030) to intercept and cache in memory for bandwidth modification andwhich content to pass through to the appropriate end users. Theselection is based on analyzing the destination address for thedownstream traffic and determining whether the destination maps to acongested service region. The mapping of destination address to theservice regions is specified in the condition parameters that are pulledfrom the carrier network databases. In some embodiments, the addressingfor the downstream traffic and service regions is specified using IPaddresses, IP addresses and port numbers, session identifiers, or otheridentifiers. In some embodiments, the process caches content that ispart of a large file download, video stream, or audio stream. Othersmaller content is passed through. Such content can be identified fromthe protocols being used and the protocol header values.

The process determines (at 1040) an amount of bandwidth to allocate whenforwarding the cached content to the requesting end users. The bandwidthallocation is based on the carrier network condition parameters thatidentify the amount of congestion at a particular service region.Depending on the amount of congestion, the process can allocate greateror less bandwidth. The process forwards (at 1050) the cached contentthrough the carrier network to the requesting end users at a rate thatis determined based on the allocated amount of bandwidth.

In this manner, the capacity management agent transparently improvescapacity of the carrier network without transcoding or otherwisealtering the content that is being streamed from external data networks.The carrier network, end users, and content providers are unaware andunaffected by the bandwidth management. Moreover, such bandwidthmanagement is effective for wireless carrier networks as end usermobility is managed by the carrier network and does not impact thecapacity management agent's ability to modify bandwidth. Therefore, thebandwidth management is effective even when end users are handed overfrom one service region to another. The bandwidth management can also bedynamically updated so that when an end user is handed over from acongested service region to an uncongested service region, the capacitymanagement agent can identify the movement of the end user between theservice regions and alter the bandwidth accordingly.

FIG. 11 presents a message exchange to illustrate the bandwidthmodification that is performed by the capacity management agent inaccordance with some embodiments. The figure includes an end user 1110,carrier network 1120, capacity management agent 1125, and contentprovider 1130. In this figure, it is assumed that the service region inwhich the end user 1110 is located is congested.

The end user's 1110 content request is passed (at 1140) to the carriernetwork 1120. The capacity management agent 1125 intercepts (at 1150)the content request as the carrier network 1120 passes the contentrequest to the content provider 1130 through an external data network.The capacity management agent 1125 may modify the content request ifsupported by the content provider 1130. The capacity management agentpasses (at 1155) the unmodified or modified content request to thecontent provider 1130.

Based on previously pulled (at 1160) carrier network conditionparameters, the capacity management agent 1125 determines that theservice region from which the content request originates is congested.Therefore, data that is streamed to that location should be bandwidthlimited.

The content provider 1130 returns the requested content to the carriernetwork 1120. In this figure, the content provider 1130 sends (at 1165)the content at a first rate that consumes 160 kbps of bandwidth. Thecapacity management agent 1125 is positioned to receive the contentbefore it reaches the carrier network 1120. The capacity managementagent 1125 analyzes the content to determine its destination. Upondetecting that content is intended for the end user 1110 that is locatedwithin the congested service region, the capacity management agent 1125intercepts and caches the content to memory. Next, the capacitymanagement agent 1125 determines the amount with which to throttle thedownstream bandwidth to the end user 1110. This determination is basedon the carrier network condition parameters and the amount of congestionat the service region. The network condition parameters are continuallypolled by the capacity management agent 1125 in order to retain areal-time status for the carrier network conditions. The capacitymanagement agent forwards (at 1170) the cached content to the end user1110 through the carrier network at a second rate that is less than thefirst rate. In this figure, the second rate consumes 64 kbps ofbandwidth. By reducing the allotted bandwidth from 160 kbps to 64 kbps,the capacity management agent 1125 conserves 96 kbps of bandwidth at thecongested service region for other end users. The end user 1110continues to receive the content albeit at a reduced rate. The end user1110 experience may be unaffected by the reduced bandwidth as someapplications dynamically adjust to the reduced rate by automaticallyadjusting the quality of the stream so that a lower quality version ofthe content is streamed from the content provider.

In some embodiments, the capacity management agent adaptively modifiesthe allocated amount of bandwidth as the carrier network conditionschange. Therefore, during a single streaming session, the capacitymanagement agent may stream content at a first rate when a particularservice region at which an end user is located is congested, stream thecontent at a second rate when the particular service region is lesscongested, and stream the content at a third rate when the particularservice region is even less congested. This adaptive modificationsimilarly applies when the end user is handed over from a congestedservice region to a less or more congested service region.

In some embodiments, the capacity management agent performs bandwidthmodification to better monetize the available resources of the carriernetwork and to provide QoS controls. FIG. 12 presents a process 1200performed by the capacity management agent to modify bandwidth forpurposes of monetizing the available resources of the carrier network inaccordance with some embodiments.

The process receives (at 1210) data that is being streamed from anexternal data network to an end user of the carrier network. The processanalyzes (at 1220) the data to identify the end user to which the datais being sent. The process retrieves (at 1230) the end user's subscriberinformation from the databases of the carrier network or from a localdatabase that stores a copy of the end user subscriber information. Fromthe retrieved end user subscriber information, the process (at 1240)determines whether the end user is provided unlimited access or whetherthe end user pays for each unit of data that is downloaded from thecarrier network (i.e., pay-per-access plan).

For an end user with unlimited access, the process reduces (at 1250) thebandwidth that is allocated for sending data to the end user. Asdescribed above, bandwidth is reduced by caching the data at thecapacity management agent and passing the data from the cache to the enduser using a reduced bandwidth. For an end user with pay-per-access, theprocess passes (at 1260) through the data to the end user withoutmodifying the bandwidth for that end user so that the pay-per-access enduser is able to consume more data than an unlimited access end user.

FIG. 13 presents a process 1300 performed by the capacity managementagent to modify bandwidth for purposes of providing QoS controls inaccordance with some embodiments. As in FIG. 12 above, the processreceives (at 1310) data that is being streamed from an external datanetwork to an end user of the carrier network. The process analyzes (at1320) the data to identify the end user to which the data is being sent.The process retrieves (at 1330) the carrier network condition parametersand the end user's subscriber information. From the conditionparameters, the process determines (at 1340) whether the service regionat which the end user is located is congested. When the service regionis not congested, the process passes (at 1370) through the data to theend user without modifying the bandwidth. However, when the serviceregion is congested, the process determines (at 1350) whether the enduser is provided unlimited access or whether the end user ispay-per-access end user. For an end user with unlimited access, theprocess reduces (at 1360) the bandwidth that is allocated for sendingdata to the end user. For a pay-per-access end user, the process passes(at 1370) through the data to the end user without modifying thebandwidth. In this manner, the capacity management agent performsbandwidth modification to provide a first QoS to end users withunlimited access and a second QoS to end users with pay-per-access.

It should be apparent to one of ordinary skill in the art that resourcemonetization and QoS controls can be performed based on criteria otherthan whether the end user has unlimited access or pay-per-access. Insome embodiments, the capacity management agent can base these decisionson other end user subscriber information. For example, the capacitymanagement agent can reduce resource consumption for end users withpersonal subscriber plans without reducing resource consumption for endusers with business subscriber plans. Alternatively, the capacitymanagement agent can base its decision on the amount of data that isconsumed in the last month with high usage end users receiving bandwidthmodification to limit further resource usage.

C. Dual Modification

In some embodiments, the capacity management agent performs contentrequest modification and bandwidth modification to improve carriernetwork capacity. In some such embodiments, content request modificationis performed for those content providers that support the modifiedcontent requests and bandwidth modification is performed for thosecontent providers that do not support the modified content requests.Alternatively, bandwidth modification may be performed in addition tocontent request modification when carrier network change, when an enduser overrides settings in a modified content request, or when a contentprovider ignores settings in a modified content request.

FIG. 14 presents a process 1400 for performing content requestmodification and bandwidth modification in accordance with someembodiments. The process 1400 begins when an end user content request isintercepted by the capacity management agent. The process identifies (at1410) the content provider from the content request and determines (at1420) whether the content provider supports modifications to the contentrequest.

When modifications are not supported, the process passes (at 1460) thecontent request through the external data network to the contentprovider. Otherwise, the process monitors (at 1430) the carrier networkconditions to determine (at 1440) whether the conditions at the serviceregion at which the content request originated exceeds a usagethreshold. When the usage threshold is not exceeded indicating that theservice region is not congested, the process passes (at 1460) thecontent request through the external data network to the contentprovider. Otherwise, the process identifies (at 1445) arguments that aresupported by the identified content provider and end user parametersthat can be used in optimizing the modified content request. Using theidentified parameters and monitored conditions, the process modifies (at1450) the content request and the content request is passed (at 1460)through the external network to the identified content provider.

Next, the process receives (at 1465) the requested content as it isstreamed from the content provider. The process determines (at 1470)whether the received content satisfies the current carrier networkconditions. For example, if the content request was modified to specifya reduced rate and the content provider is streaming the requestedcontent at the reduced rate then no further modifications need to beapplied when streaming the content through the carrier network to theend user. However, the content provider may ignore the specified reducedrate within the modified content request or the carrier networkconditions may have changed requiring further modification of the streambefore it can be forwarded to the end user. When no furthermodifications are needed, the process forwards (at 1490) the contentthrough the carrier network to the end user and the process ends.However, when modifications are required, the process determines (at1480) the amount of bandwidth to allocate to the received content andthe process forwards (at 1485) the received content through the carriernetwork to the end user using the determined amount of bandwidth. Thoughthe process 1400 is shown for a single content request and a singlecontent stream, it should be apparent that the process 1400 operatesover multiple simultaneous content requests and multiple simultaneouscontent streams.

III. Computer System

Many of the above-described processes and components are implemented assoftware processes that are specified as a set of instructions recordedon a computer readable storage medium (also referred to as computerreadable medium). When these instructions are executed by one or morecomputational element(s) (such as processors or other computationalelements like ASICs and FPGAs), they cause the computational element(s)to perform the actions indicated in the instructions. Computer andcomputing machine is meant in its broadest sense, and can include anyelectronic device with a processor including cellular telephones,smartphones, portable digital assistants, tablet devices, laptops,notebooks, servers, and desktop computers. Examples of computer readablemedia include, but are not limited to, CD-ROMs, flash drives, RAM chips,hard drives, EPROMs, etc.

FIG. 15 illustrates a computer system or server with which someembodiments are implemented. Such a computer system includes varioustypes of computer readable mediums and interfaces for various othertypes of computer readable mediums that implement the various processesand modules described above (e.g., the capacity management agent).Computer system 1500 includes a bus 1505, a processor 1510, a systemmemory 1515, a read-only memory 1520, a permanent storage device 1525,input devices 1530, and output devices 1535.

The bus 1505 collectively represents all system, peripheral, and chipsetbuses that communicatively connect the numerous internal devices of thecomputer system 1500. For instance, the bus 1505 communicativelyconnects the processor 1510 with the read-only memory 1520, the systemmemory 1515, and the permanent storage device 1525. From these variousmemory units, the processor 1510 retrieves instructions to execute anddata to process in order to execute the processes of the invention. Theprocessor 1510 is a processing device such as a central processing unit,integrated circuit, graphical processing unit, etc.

The read-only-memory (ROM) 1520 stores static data and instructions thatare needed by the processor 1510 and other modules of the computersystem. The permanent storage device 1525, on the other hand, is aread-and-write memory device. This device is a non-volatile memory unitthat stores instructions and data even when the computer system 1500 isoff. Some embodiments of the invention use a mass-storage device (suchas a magnetic or optical disk and its corresponding disk drive) as thepermanent storage device 1525.

Other embodiments use a removable storage device (such as a flash drive)as the permanent storage device. Like the permanent storage device 1525,the system memory 1515 is a read-and-write memory device. However,unlike storage device 1525, the system memory is a volatileread-and-write memory, such a random access memory (RAM). The systemmemory stores some of the instructions and data that the processor needsat runtime. In some embodiments, the processes are stored in the systemmemory 1515, the permanent storage device 1525, and/or the read-onlymemory 1520.

The bus 1505 also connects to the input and output devices 1530 and1535. The input devices enable the user to communicate information andselect commands to the computer system. The input devices 1530 includealphanumeric keypads (including physical keyboards and touchscreenkeyboards), pointing devices (also called “cursor control devices”). Theinput devices 1530 also include audio input devices (e.g., microphones,MIDI musical instruments, etc.). The output devices 1535 display imagesgenerated by the computer system. The output devices include printersand display devices, such as cathode ray tubes (CRT) or liquid crystaldisplays (LCD).

Finally, as shown in FIG. 15, bus 1505 also couples computer 1500 to anetwork 1565 through a network adapter (not shown). In this manner, thecomputer can be a part of a network of computers (such as a local areanetwork (“LAN”), a wide area network (“WAN”), or an Intranet, or anetwork of networks, such as the internet. For example, the computer1500 may be communicably coupled through the network 1565 to an ingestserver, mid-tier server, edge server, content provider streaming server,or end user device.

As mentioned above, the computer system 1500 may include one or more ofa variety of different computer-readable media. Some examples of suchcomputer-readable media include RAM, ROM, read-only compact discs(CD-ROM), recordable compact discs (CD-R), rewritable compact discs(CD-RW), read-only digital versatile discs (e.g., DVD-ROM, dual-layerDVD-ROM), a variety of recordable/rewritable DVDs (e.g., DVD-RAM,DVD-RW, DVD+RW, etc.), flash memory (e.g., SD cards, mini-SD cards,micro-SD cards, etc.), magnetic and/or solid state hard drives, ZIP®disks, read-only and recordable blu-ray discs, any other optical ormagnetic media, and floppy disks.

While the invention has been described with reference to numerousspecific details, one of ordinary skill in the art will recognize thatthe invention can be embodied in other specific forms without departingfrom the spirit of the invention. Thus, one of ordinary skill in the artwould understand that the invention is not to be limited by theforegoing illustrative details, but rather is to be defined by theappended claims.

1. For a carrier network comprising a plurality of service regions thatprovide wireless data access to data of an external data network, amethod for transparently managing capacity of the carrier network, themethod comprising: receiving data from the external data network that isintended for a particular service region of the carrier network;identifying resource availability at the particular service region;passing said data to the particular service region through the carriernetwork at a first rate when the resource availability at the particularservice region is not less than a threshold amount; and caching saiddata for subsequent passing to the particular service region through thecarrier network at a second rate when the resource availability at theparticular service region is less than the threshold amount, wherein thefirst rate is greater than the second rate.
 2. The method of claim 1,wherein identifying resource availability comprises identifying at leastone of (i) a measure of congestion and (ii) a measure of availablebandwidth at the particular service region.
 3. The method of claim 2,wherein the first rate comprises a first bitrate, the second ratecomprises a second bitrate, and wherein the first bitrate consumesgreater bandwidth than the second bitrate.
 4. The method of claim 1further comprising computing the second rate based on the identifiedresource availability at the particular service region.
 5. The method ofclaim 4 further comprising adjusting the second rate as the resourceavailability at the particular service region changes.
 6. The method ofclaim 4 further comprising adjusting the second rate when said data ispassed to a different service region of the carrier network.
 7. Themethod of claim 1, wherein receiving the data comprises analyzing thedata to identify a destination address for the particular serviceregion.
 8. The method of claim 1 further comprising passing cached dataat the second rate when the resource availability at the particularservice region is less than the threshold amount and wherein passingcached data at the second data reduces resource usage than when passingdata at the first rate.
 9. The method of claim 1 further comprisingreceiving a request for content that originates from the particularservice region of the carrier network and that is intended for aparticular content provider of the external data network.
 10. The methodof claim 9 further comprising modifying the request when the resourceavailability at the particular service region is less than the thresholdamount, wherein modifying the request reduces resource usage for thecontent that is passed from the particular content provider through thecarrier network to the particular service region in response to themodified request.
 11. The method of claim 10, wherein modifying therequest comprises at least one of (i) appending a query string argumentto a Uniform Resource Locator (URL) that is specified within therequest, (ii) inserting a header field and value to a header of therequest, and (iii) modifying a URL that is specified within the requestto redirect the request from a first destination to a seconddestination.
 12. For a carrier network comprising a plurality of serviceregions that provide wireless data access to data of an external datanetwork, a method comprising: receiving data from the external datanetwork that is intended for an end user at a particular service regionof the carrier network; identifying subscriber information for the enduser; passing said data to the particular service region through thecarrier network at a first rate when the subscriber informationidentifies a first subscriber; and caching said data for subsequentpassing to the particular service region through the carrier network ata second rate when the subscriber information identifies a secondsubscriber, wherein the first rate is greater than the second rate. 13.The method of claim 12, wherein the first subscriber is an end user witha pay-per-access plan and the second subscriber is an end user with anunlimited access plan.
 14. The method of claim 12, wherein the firstsubscriber is provided a quality of service that allows for greatercarrier network resource consumption than the second subscriber.
 15. Themethod of claim 12 further comprising identifying resource availabilityat the particular service region and passing said data to the particularservice region through the carrier network at the first rate when thesubscriber information identifies the second subscriber and when theresource availability at the particular service region is not less thana threshold amount.
 16. The method of claim 12, wherein passing the dataat the first rate consumes a greater amount of bandwidth than passingthe data at the second rate.
 17. A capacity management agent comprising:a network interface (i) for receiving data that passes between at leastone service region of a carrier network and an external data network and(ii) for receiving, from the carrier network, condition parameters thatidentify resource usage at the service region; and a processor (i) forpassing data from the external data network through the networkinterface to the service region at a first rate when the resource usageat the service region does not satisfy a threshold amount and (ii) forpassing data from the external data network at a reduced second ratethrough the network interface to the service region when the resourceusage at the service region satisfies the threshold amount.
 18. Thecapacity management agent of claim 17 further comprising memory forcaching said data to allow for passing of the data at the reduced secondrate.
 19. The capacity management agent of claim 17, wherein theprocessor is (i) further for analyzing data from the external datanetwork to determine that the destination for the data is the serviceregion and (ii) further for retrieving condition parameters for theservice region from the carrier network.
 20. The capacity managementagent of claim 17, wherein the interface comprises a broadband interfaceto a Gateway GPRS Support Node (GGSN) of the carrier network.